Electric Field Poling Of Quasi-Phase-Matched Optical Fibres

Nonlinear Guided Waves and Their Applications Pub Date : 1997-11-01 DOI:10.1364/JOSAB.14.003170

P. Kazansky, V. Pruneri

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引用次数: 48

Abstract

Ten years have passed since the discovery of photoinduced quasi-phase-matched second harmonic generation in optical fibres [1-3]. However, until fairly recently, second harmonic generation in optical fibres has been more of scientific than practical interest, owing to the low levels of induced nonlinearity (~10-3 pm/V, which is four orders of magnitude less than in inorganic crystals, e.g. lithium niobate). The mystery of photoinduced χ(2) gratings was finally solved on the basis of the coherent photogalvanic effect [4]: a high (104-5 V/cm) spatially oscillating electrostatic field appears in glass as a result of charge separation induced by coherent photocurrent, oscillating with a period determined by the coherence length; this electric field produces a quasi-phase-matching χ(2) grating in proportion to χ(3). The conversion efficiency reported in the first experiments on photoinduced SHG-~ 5 % from a peak pump power of ~ 20 kW-is still among the highest conversion efficiencies achieved so far in optical fibres. The reasons for these relatively high conversion efficiencies has to be searched in the long length (tens of centimetres) and good uniformity of the photoinduced gratings.

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准相位匹配光纤的电场极化

光纤中发现光致准相位匹配二次谐波已经十年了[1-3]。然而，直到最近，光纤中的二次谐波产生的科学意义大于实际意义，这是由于诱导非线性水平低(~10-3 pm/V，比无机晶体(如铌酸锂)低4个数量级)。光致χ(2)光栅的奥秘最终在相干光电效应的基础上得到了解决[4]:由于相干光电流引起的电荷分离，玻璃中出现了一个高(104-5 V/cm)的空间振荡静电场，振荡周期由相干长度决定;该电场产生与χ(3)成比例的准相位匹配χ(2)光栅。在光诱导SHG的第一次实验中报告的转换效率-约5%，峰值泵浦功率约20千瓦-仍然是迄今为止在光纤中实现的最高转换效率之一。这些相对较高的转换效率的原因必须在长(几十厘米)和光致光栅的良好均匀性中寻找。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Nonlinear Guided Waves and Their Applications

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